Sachin A. Reddy, T. Nordheim, Camilla D. K. Harris
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引用次数: 0
摘要
欧罗巴表面不断受到来自电离层和木星磁层的等离子体流的影响。当这些粒子流到表面时,就会形成静电表面电势。我们利用三维粒子入胞模拟研究了木卫二表面的静电荷。我们发现,木卫二的表面电势从-14 V到-52 V不等。预测的表面电势随木卫二的位置、光照条件、等离子体环境和表面特性而变化。我们发现电离层具有显著的 "阻尼效应",限制了大负表面电势的形成。此外,我们发现二次发射是决定欧罗巴表面电荷的关键因素。我们讨论了即将进行的任务(如 Europa Clipper 和 JUICE)如何远程探测这种电势。我们的研究结果还可能有助于设计未来前往欧罗巴表面的任务,如登陆器和其他机器人探测器。
Europa’s surface is exposed to a constant flow of plasma from its ionosphere and Jupiter’s magnetosphere. As these particles flow onto the surface, an electrostatic surface potential forms. We investigate the electrostatic charging of Europa’s surface using 3D particle-in-cell simulations. We find that surface potentials on Europa vary from −14 to −52 V. The predicted surface potentials vary as a function of location on Europa, illumination conditions, plasma environment, and surface properties. We reveal that the ionosphere has a significant “dampening effect,” limiting the formation of large negative surface potentials. Furthermore, we find that secondary emission is a key factor in determining the surface charge on Europa. We discuss how such potentials may be remotely detected by upcoming missions, such as Europa Clipper and JUICE. Our results may also be of use in the design of future missions to Europa’s surface, such as landers and other robotic explorers.
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